Laser-Enhanced Biomorphic Scaffolds Support Multipotent Stem Cell Differentiation and Angiogenesis for Vascularised Bone Regeneration.

Kumar, S.; Iqbal, N.; Pan, Y.; Daskalakis, E.; Owston, HE.; Raif, EM.; Ganguly, P.; Loganathan, S.; Giannoudis, PV.; Jha, A.

Laser-Enhanced Biomorphic Scaffolds Support Multipotent Stem Cell Differentiation and Angiogenesis for Vascularised Bone Regeneration.

All Authors

Kumar, S.

Iqbal, N.

Pan, Y.

Daskalakis, E.

Owston, HE.

Raif, EM.

Ganguly, P.

Loganathan, S.

Giannoudis, PV.

Jha, A.

LTHT Author

Ganguly, Payal
Giannoudis, Peter V

LTHT Department

NIHR Leeds Biomedical Research Centre
Orthopaedics

Publication Date

2026

Item Type

Journal Article

Subject

HOSPITALISATION , BONE MARROW , BONE TRANSPLANTATION

Abstract

Biomorphic hydroxyapatite scaffolds derived from rattan wood (GreenBone) show significant promise in bone tissue engineering due to their inherent structural similarity to natural bone. Laser-drilled GreenBone scaffolds were studied for enhanced porosity, nutrient diffusion, cellular infiltration, and vascularisation. Patient-derived bone marrow mesenchymal stromal/stem cells (BMMSCs) and culture-expanded mesenchymal stem cells (cMSCs) demonstrated high cell viability (>90%), considerable adhesion, and extensive cytoskeletal organisation. Trilineage differentiation confirmed the multipotency of BMMSCs, with osteogenic, adipogenic, and chondrogenic markers being successfully expressed. BMMSCs and cMSCs exhibited enhanced differentiation and gene expression profiles. At week 4, key osteogenic and angiogenic genes such as BMP2, VEGFC, RUNX2, and COL1A1 showed elevated expression, indicating improved bone formation and vascularisation activity. Markers associated with extracellular matrix (ECM) remodelling, including MMP9 and TIMP1, were also upregulated, suggesting active tissue remodelling. ELISA analysis for VEGF further demonstrated increased VEGF secretion, highlighting the scaffold's angiogenic potential. The improved cellular response and vascular signalling emphasise the translational relevance of laser-modified GreenBone scaffolds for bone tissue engineering, particularly for critical-sized defect repair requiring rapid vascularised bone regeneration.